Abstract
Recently, the development of the ultra-high-voltage hybrid AC/DC power systems brings not only positive effect such as large-scale resources’ optimal allocation to release the intense resource situation in China, but also negative one such as great challenges to the safe and stable operation of power systems, which brings great strength to the whole power systems. Especially with the larger scale and capacity of DC feeding to the same receiving end, one AC fault in the power system may cause cascading AC/DC failure, which may be worse cause the simultaneous commutation failure of multiple DC lines. The simultaneous commutation failure of multiple DC lines will increase the risk of large capacity loss in the power systems. To maximally guarantee the power supply of local important load, active splitting is deemed to be an effective method. In this paper, the receiving-end grid with multiple DC lines feeding to is considered. Firstly, the research results of active splitting strategies got by the researchers are listed, and the different technologies of active splitting strategies are also mentioned. Secondly, the scenarios in which transient instability of the whole power system happen in the severe AC and DC cascading failure are analyzed. One is the instability of the whole system caused by DC blocking of multiple DC lines, along with the invalid out-of-step splitting, the other is the failure of stability control device which is deal with the problem of transient instability of local power grid. To avoid the local important loads going instability with main power systems when the extreme severe faults happen, the general framework of active splitting strategies is designed. The framework is according to the specific instability characteristic of the scenarios mentioned before, and in the meantime, the trigger criteria of active splitting strategies are also proposed, as well as the chosen principles of the active splitting surfaces. When the transient instability of whole power system occurs, the active splitting strategies take responsibility for the safe and stable operation of the local important loads by splitting the decided active splitting surfaces triggered by the active splitting signals (including the capacity of DC blocking provided by the active splitting primary control stations, the signals of line voltage and power angle provided by wide-area measurement system (WAMS)), and along with the additional emergency control (usually including the load shedding) which is taking advantages of the WAMS. Finally, the active strategies are confirmed to be effective by verifying in an actual power system, and the simulation results turn out that the active splitting strategies with specific selection of active splitting surfaces and emergency control can be utilized to deal with the severe faults in ultra-high-voltage hybrid AC/DC power systems.
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Yu X, Zhang X, Zhong Y, et al (2014) Cascading failure model of AC-DC system and blackout risk analysis. Autom Electr Power Syst 38(19):33–39
Li M (2016) Characteristic analysis and operational control of large-scale hybrid UHV AC/DC power grids. Power Syst Technol 40(4):985–991
Fang Y (2012) Lessons from September 8, 2011 Southwest America blackout for prevention and control of cascading outages. Autom Electr Power Syst 36(15):1–7
Wang J, Liang Z, Jiang M et al (2015) Case analysis and simulation of commutation failure in multi-infeed HVDC transmission systems. Autom Electr Power Syst (4):141–146
Wang K, Cui X, Ye M et al (2015) Block strategies of the sever faults of Guangzhou power grid. Power Syst Prot Control 12:123–128
Xia C, Chen C, Tu L et al (2016) Applicability analysis of out-of-step splitting criteria under multi-frequency oscillation. Autom Electr Powre Syst 4:26–31
Feng K, Zhang Y, Liu Z, et al (2015) A new scheme for out-of-step splitting considering drift of oscillation center. Power Syst Technol 39(4):1082–1087
Zhang Y, Meng G, Zhao R, et al (2015) Locating of out-of step centre and mechanism of oscillation center migrating under complicated scenes. Power Syst Technol 39(8):2264–2269
Chen E, Tang F, Liu D et al (2014) Splitting strategy of power systems based on migration of oscillation center. Proc CSEE 34(22):3799–3805
Wang Y, Tang Y, Ding L et al (2013) Research and development of new wide area out-of step control technology for power systems. Power Syst Technol 37(7):1827–1833
Shen C, Wu J, Qiao Y et al (2006) Studies on active splitting control of power system. Proc CSEE 26(13):1–6
Song H, Wu J (2013) A summarization of research on wide-area measurement information based power system controlled islanding. Power Syst Technol 37(12):3467–3474
Fang Y, Liu F, Li B. A review of out-of-step oscillation islanding control of large scale power systems. Proc CSEE 2017(37)
Song H, Wu J, Hao L (2014) A searching method for power system controlled islanding surfaces considering coherency constraint. Autom Electr Power Syst 38(14):49–54
Wang D, Xue Y, Wu QH, et al (2009) Optimization and coordination of fault-driven splitting and out-of-step splitting. Autom Electr Power Syst 33(14):1–6, 16 (in Chinese)
Liu F, Yang W, Huang Z, et al. Security stability control method based on system response measurement. Proc CSEE 2009(s1):25–28
Liu F, Fang Y, Li W et al (2014) Out-of step oscillationcenter change rules and its location under multi-frequency oscillation. Autom Electr Power Syst 38(20):68–73
Zhao L, Li X, Ni M, et al (2014) Review and prospect of research on hidden failures of protection system and security and stability control system. Autom Electr Power Syst 38(22):128–135
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Wang, Y. et al. (2020). Active Splitting Strategies Based on Severe Faults of Hybrid AC/DC Power Systems. In: Xue, Y., Zheng, Y., Rahman, S. (eds) Proceedings of PURPLE MOUNTAIN FORUM 2019-International Forum on Smart Grid Protection and Control. PMF PMF 2019 2021. Lecture Notes in Electrical Engineering, vol 584. Springer, Singapore. https://doi.org/10.1007/978-981-13-9779-0_32
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DOI: https://doi.org/10.1007/978-981-13-9779-0_32
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